Catalytic incineration of hydrogen sulfide from gas streams

ABSTRACT

A process for the conversion of H 2  S to SO 2  in a feed gas containing H 2  S is effected by oxidation with air or oxygen at temperatures between 300° and 900° F. The oxidation is conducted in the presence of an extremely stable oxidation catalyst comprising an oxide and/or sulfide of vanadium supported on a non-alkaline porous refractory oxide. The preferred catalyst comprises between 5 and 15 wt. % V 2  O 5  on hydrogen mordenite or alumina. Hydrogen, carbon monoxide, light hydrocarbons, and ammonia present in the feed gas are not oxidized. The invention is especially contemplated for use in treating waste gases from geothermal steam power plants.

CROSS-REFERENCE TO RELATED APPLICATIONS

This is a continuation-in-part of copending application Ser. No. 605,639, filed Aug. 18, 1975, and now abandoned.

BACKGROUND AND SUMMARY OF THE INVENTION

Current air pollution regulations in most industrialized parts of the world are very restrictive concerning the amounts of H₂ S industry can discharge into the atmosphere. Los Angeles, for example, requires that no more than 10 ppmv be so discharged. The discharge requirements of SO₂, however, are not nearly so restrictive. Los Angeles waste gas streams containing up to 500 ppmv SO₂ can be safely discharged while Canada and Germany allow up to 2000 and 4000 ppmv, respectively. As a result, there is provided by law a strong incentive for industries engaged in such diverse activities as petroleum refining, meat packing, soap production, sewage treatment, electrical generation, and chemical production to convert the H₂ S in their waste gas streams to SO₂ prior to atmospheric discharge. The manner in which this is presently accomplished is through the use of a stack gas incinerator, i.e., by blending sufficient natural gas or other fuel with the waste gas stream to provide a combustible mixture, and then burning the resultant mixture in the temperature range of 1350°-1550° F. at the point of discharge.

With the advent of the energy crisis another incentive has been provided to industry--namely, that of saving expensive fuel. Ideally, therefore, it would be most desirable to oxidize the H₂ S to SO₂ catalytically, without adding fuel. The development of a catalytic incinerator, however, has been hampered by the fact that waste gas streams containing H₂ S usually also contain in uncombustible amounts such highly oxidizable components as CO, H₂, and light hydrocarbons, which, if oxidized in a catalytic incinerator would release large quantities of heat and hence increase the operating temperature of the catalytic incinerator to undesirable levels. Consequently, most catalytic incinerators need cooling facilities which may necessitate as much energy input, and more maintenance requirements, than burning in a stack gas incinerator.

From the preceding discussion, it is apparent that for a catalytic incinerator to be most effective it must be selective for the oxidation of H₂ S to SO₂. A major objective of the invention, therefore, is to provide a novel process for selectively incinerating H₂ S in the presence of other normally oxidizable components. Another objective is to provide novel catalysts for effecting the selective incineration of H₂ S to SO₂. Another objective is to utilize the catalytic incineration process of the invention for treating vent gases emanating from geothermal power plants.

The present invention is a revised version of a known catalytic incineration process largely abandoned by the art. In United Kingdom Pat. No. 733,004, published Jan. 23, 1953, it is taught that a catalyst composed of 5-10 weight-percent V₂ O₅ on alumina is effective in reducing H₂ S concentrations in Claus tail gas streams by converting the same to SO₂. However, no mention is made therein that said catalyst is selective for the incineration of H₂ S to SO₂ in the presence of H₂, CO, light hydrocarbons, or ammonia.

By the process of the present invention it has been found that catalysts composed of 5-15 weight-percent V₂ O₅ on alumina, hydrogen mordenite, or any other non-alkaline, porous refractory oxide are very selective for the oxidation of H₂ S to SO₂ in the presence of H₂, CO, light hydrocarbons, or ammonia. Even more surprisingly, it has been found that these normally oxidizable components of H₂, CO, light hydrocarbons, and ammonia remain unoxidized even when excess air is utilized to perform the H₂ S to SO₂ conversion. Furthermore, conversions of H₂ S to SO₂ are essentially 90 to 100 percent complete and space velocities varying in the wide range of 1,000 to 100,000 GHSV can be utilized. Operating temperatures can vary from a minimum of 300° to a maximum of about 900° F. Also, no detectable amount of SO₃ is formed when hydrogen is a component of the feed gas or when temperatures below about 500° F. are utilized when hydrogen is not a component of the feed gas.

All gas space velocity data herein are reported in terms of volumes of gas (calculated at one atmosphere and 60° F.) passing through one volume of catalyst per hour.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawing designated FIG. 1 is a simplified flow diagram illustrating a preferred effluent-gas-recycle embodiment of the invention.

FIG. 2 is a simplified flow diagram illustrating a method for applying the invention to purification of off-gases from geothermal power plants. Similar apparatus components in FIGS. 1 and 2 are designated by the same reference numeral.

DETAILED DESCRIPTION OF THE INVENTION

This invention is particularly concerned with the selective oxidation of H₂ S to SO₂ in a feed gas comprising H₂ S and any of the relatively inert inorganic gases such as nitrogen, carbon dioxide, water vapor, argon, helium, neon, etc., and/or any of the normally oxidizable components such as H₂, CO, light hydrocarbons, and ammonia. As used herein, the term "light hydrocarbons" refers to those saturated hydrocarbons containing no more than six carbon atoms. Many other gases may be present in the feed gas but, as those skilled in the art will readily understand, the remaining gaseous components (except for sulfur vapor as will be shown hereinafter) should be chemically inert under the conversion conditions specified herein, and should not adversely affect or poison the catalyst. The process is particularly contemplated for the catalytic oxidation of H₂ S present in waste gas streams which discharge from petroleum refineries, sewage plants, meat packing plants, geothermal power plants, soap factories, and chemical manufacturing plants. Additionally, the process is useful in situations wherein it is desired to reduce the H₂ S content of sour natural gases, sour refinery gases, etc.

In general, the process of the invention is suitable for treating feed gases containing 10 ppmv-10 mole % H₂ S, usually 10 ppmv-5 mole % H₂ S, and at least about 100 ppmv of one or more components selected from the class consisting of hydrogen, carbon monoxide, ammonia, and light hydrocarbons. The process is most advantageously utilized for treating "sour" gases containing at least about 50, usually about 100 ppmv - 5 mole % of H₂ S, and at least about 100, usually at least about 500 ppmv, of at least one oxidizable component selected from the class consisting of hydrogen, carbon monoxide, ammonia, and light hydrocarbons. Other components found in the feed gases usually consist of one or more of: CO₂, N₂, H₂ O, O₂, SO₂, and COS.

The basic process can be more readily understood by reference to the accompanying FIG. 1. A feed gas directed through lines 1, 2, 4, and 5 is blended with an oxygen-containing gas, preferably air, from line 6 so that the resultant mixture in conduit 7 preferably contains more than the stoichiometric amount of oxygen necessary to convert the H₂ S therein to SO₂. This mixture in conduit 7 is passed to a suitable preheater 8 to heat the gases to at least about 300° F., preferably to some temperature between about 300° and 900° F. The heated mixture is then fed through lines 9 and 10 to the catalytic incinerator 11 at a space velocity of at least 100 v/v/hr, usually between 1,000 and 100,000 v/v/hr, and preferably between about 2,000 and 20,000 v/v/hr when a temperature in the 600°-900° F. range is used and between about 1000 and 5000 v/v/hr when a temperature in the 300°-800° F. range is used. The gases contact a catalyst in incinerator 11, which catalyst comprises one or more vanadium oxides and/or sulfides supported on a non-alkaline, porous refractory oxide. This catalyst, described in fuller detail hereinafter, is highly active for the conversion of H₂ S to SO₂, and, depending upon the space velocity and temperature utilized, can effect H₂ S conversions at least about 80%, usually between about 90 and 100%, complete. Furthermore, the catalyst is so selective for the oxidation of H₂ S that such highly oxidizable components as H₂, CO, ammonia, and light hydrocarbons, any or all of which might be present, remain almost completely unoxidized, thus greatly reducing the overall amount of heat generated.

As those skilled in the art will realize, the proportion of H₂ S converted to SO₂ in incinerator 11 is dependent upon the temperature maintained therein and the space velocity utilized, with the conversion increasing with increasing temperature and/or decreasing space velocity. For a 90% conversion of H₂ S to SO₂, it will usually be found that any temperature between 600° and 900° F. and a space velocity up to about 10,000 v/v/hr will suffice. Similar conversions are obtainable at temperatures between 300° and 500° F. when the space velocity is maintained below about 2500 v/v/hr and at temperatures between 500° and 600° F. when the space velocity is maintained below about 5,000 v/v/hr. For at least an 80% conversion of H₂ S to SO₂, a temperature in the 600°-900° F. range is suitable, with increasingly higher temperatures in this range being necessary for increasingly higher space velocities above 10,000 v/v/hr. An 80% or better conversion is obtainable at temperatures between 300° and 600° F. with a space velocity less than 10,000 v/v/hr, again with increasingly higher temperatures being necessary for increasingly higher space velocities approaching 10,000 v/v/hr.

A unique feature of the invention is that, when the feed gas contains H₂, CO, NH₃, light hydrocarbons, or combinations thereof, essentially none of these normally oxidizable components is oxidized in incinerator 11, even when temperatures between 600°-900° are used. This is considered surprising inasmuch as, based on thermodynamic equilibria calculations, these components should be oxidized prior to H₂ S at temperatures in the 300°-900° F. range. Evidently, however, the rates of reaction for the oxidation of H₂, CO, NH₃, and light hydrocarbons at temperatures less than 900° F. and in the presence of a vanadium oxide and/or sulfide catalyst as described are slower than that for H₂ S.

Another unique feature of the invention lies in the fact that, although a vanadia catalyst is used to convert the H₂ S in the feed gas to SO₂, at temperatures below 900° F. the use of excess air fed via line 6 does not result in the production of SO₃, provided the feed gas contains H₂ in proportions of at least about 100 ppmv, and preferably in a proportion of at least about 1.0 mol %. This result is considered surprising because vanadia catalysts are used commercially to convert SO₂ to SO₃ in the sulfuric acid industry. When treating feed gases containing essentially no H₂, either the operating temperature of incinerator 11 should be maintained below about 500° F., or only about 0.8 to 1.05 times the stoichiometric amount of air should be fed via line 6, or H₂ should be blended in with the air fed via line 6, or some combination of these operating procedures should be done to prevent the formation of more than about 10 ppmv of SO₃.

The reaction in the catalytic incinerator 11 is highly exothermic: ##EQU1## and the temperature in said incinerator will rise depending on the quantity of H₂ S present in, and the heat capacity of, the entering feed gas-oxidant mixture. For feed gas streams containing only small quantities of H₂ S the temperature rise will be relatively insignificant, thus permitting simple adiabatic operation, with the exit gas temperature being held at between about 350° and about 900° F. without means for cooling. For feed gas streams containing larger quantities of H₂ S, however, the generation of heat via Reaction (I) can become a problem. In one embodiment, therefore, the gases in the reactor are cooled externally by indirect heat exchange so that the conversion of H₂ S to SO₂ takes place more or less isothermally; in this embodiment, the feed gas-oxidant mixture can be preheated to any desired isothermally-held incinerator temperature between about 300° and 900° F., preferably between about 500° and 850° F.

In commercial practice, however, it is a substantial impossibility to maintain true isothermal conditions. Hence, if the temperature, H₂ S content, and heat capacity of the influent gases are such that adiabatic operation would result in temperatures exceeding about 900° F., one or more internal temperature control measures may be adopted. In a preferred embodiment, the influent gases are diluted with sufficient additional oxidant gas that, when the total mixture is preheated to between about 300° and about 750° F., an exit gas temperature between about 500° and about 900° F., preferably between about 600° and 850° F., is maintained. This dilution can be accomplished simply by adding more oxidant gas via line 6. Alternatively, a combined dilution-quenching technique may be utilized by admitting cool air at one or more downstream points in the incinerator via supply line 6a. If desired, a portion of the purified gas to be discharged to the atmosphere via line 12 can be recycled to line 10 via blower 13 and line 14 to provide all or a portion of the desired dilution. This latter alternative has the additional advantages of at least partially heating the fresh influent gases, thus reducing the load on preheater 8, and of allowing for further conversion of any H₂ S remaining in the recycled gases.

Although it is within the scope of the invention to blend at least 80% of the amount of oxygen necessary for the conversion of H₂ S to SO₂ with the feed gas, it is highly preferable in carrying out the oxidation that at least stoichiometric oxygen for Reaction (I) be used. If less than the stoichiometric amount is utilized, then the formation of sulfur by the Claus reaction:

    2H.sub.2 S+SO.sub.2 ⃡3S+2H.sub.2 O             (II)

becomes a distinct possibility because incineration of H₂ S to SO₂ is incomplete. The discharge of gaseous elemental sulfur may then violate other air pollution laws. Also, if the sulfur vapor were to exceed its dewpoint, it would condense on the catalyst and incinerator surfaces. This would then result in deactivation of the catalyst and, possibly, plugging of the incinerator. Lastly, some H₂ S would remain unreacted and the purpose of the incinerator might be defeated. Thus, although the use of less than stoichiometric oxygen may be found feasible or utilitarian in some instances, it is recommended that oxygen, preferably in the form of air, should be used in any excess amount above that required for Reaction (I), usually up to about 5.0 times stoichiometric. Preferably between about 1.1 and 5.0 times the stoichiometric amount is so used.

One very desirable feature of the invention is that Reaction (I) has an extremely favorable equilibrium constant (i.e., K_(P) 400° F.=4.98×10⁵²) for the production of SO₂. As a result, the process is most useful for treating feed gases containing substantial amounts of water vapor.

There are several situations in which it is foreseen that control of the effluent gas SO₂ concentration and/or temperature is, if not necessary, at least desirable. For example, if the H₂ S concentration of the feed gas-oxidant mixture is excessive, the product SO₂ concentration may itself violate air pollution laws. Also, in the absence of means for external cooling, the processing of gases containing high concentrations of H₂ S would, because of the exothermic nature of Reaction (I), result in effluent gas temperatures in excess of the desired maximum operating temperature. At temperatures above about 500° F. when no H₂ is present or at temperatures above about 900° F. when H₂ is present, some SO₂ produced in incinerator 11 may be converted to SO₃, which, in addition to being a more noxious air pollutant than either H₂ S or SO₂, might also attack the catalyst support. Also, if hydrogen is present, operating at above 900° F. may bring about a combination of hydrogen with oxygen to form water and/or a combination of hydrogen with SO₂ to form the original starting material, H₂ S:

    so.sub.2 +3h.sub.2 →h.sub.2 s+2h.sub.2 o            (iii)

fortunately, none of these problems arises when the process is operated to control both the temperature and the SO₂ concentration in the effluent gas, as will now be explained.

In a preferred embodiment of the invention, simultaneous control of temperature and SO₂ concentration in the exit gas is effected by diluting the feed gas with air via line 6, recycle gases via line 14, externally derived gases (not referenced in FIG. 1), or any combination thereof, so that the resultant mixture entering the incinerator via line 10 contains some predetermined maximum H₂ S concentration. (Alternatively, all or a portion of the oxygen can be added via line 6a instead of line 6 to achieve the same ultimate objectives of control of exit gas temperature and SO₂ concentration.) Since the catalyst is selective for the oxidation of H₂ S, any adiabatic temperature rise in the incinerator is due almost exclusively to the exothermic nature of Reaction (I). Thus, assuming the heat capacity of the gases within the incinerator remains relatively constant during the oxidation of the H₂ S, the temperature rise therein is directly proportional to the concentration of H₂ S in the feed gas-oxidant mixture:

    .sup.T exit-.sup.T inlet=CM

(where M is the H₂ S concentration in mole % and C is the proportionating constant, hereinafter termed the temperature rise coefficient, in ° F./mole%). Therefore, in the preferred embodiment, the feed gas-oxidant mixture is heated to some temperature between about 300° and 750° F. such that a predetermined maximum concentration of H₂ S in said mixture will produce a predetermined maximum exit gas temperature in the range of about 500°-900° F. When operated in this manner, the process normally results in incineration of at least about 95%, and usually between about 98 and 100%, of the available H₂ S to SO₂. The following hypothetical Example is illustrative of the points discussed above. (All Examples herein are illustrative only and are not intended to be limiting).

EXAMPLE I

A Canadian industry must discharge a hydrogenated Claus tail gas (hydrogenated to convert all sulfur compounds to H₂ S as described, e.g., in Canadian Pat. No. 918384). The gas contains 3 mole % H₂ S and a substantial amount of hydrogen. To avoid the production of SO₃, or H₂ S (by Reaction (III)), it is specified that the exit gas temperature of the incinerator be no more than 750° F. It is also necessary to maintain the exit gas SO₂ concentration at 2000 ppmv, the maximum permissible discharge limit. Thus, air must be added to the feed gas stream such that the ratio of feed gas to air in the resultant mixture is 1:14. Assuming the temperature rise coefficient of this mixture is 205° F./mole % H₂ S oxidized to SO₂, and assuming 100% conversion of H₂ S to SO₂, the preheater need only heat the mixture to 709° F. (750-T=205×0.2; T=709). The preheated mixture of feed gas and air enters the incinerator and contacts a catalyst comprising 10 weight % V₂ O₅ on hydrogen mordenite, which catalyst is effective for the exothermic oxidation of H₂ S to SO₂. Once the exit gas achieves a temperature of 750° F., a portion of it may be recycled back to be blended with the feed gas, and the air feed suitably reduced, so that the H₂ S concentration of the gases entering the incinerator is still maintained at 0.2 mole %. However, for best results, the reduction in air feed must not be so extensive that only stoichiometric or less oxygen (for Reaction (I)) is blended into the feed gas stream.

In many cases, especially in the case of feed gases containing more than about 400 ppmv of H₂ S, it may be desirable prior to incineration to oxidize a portion of the H₂ S to elemental sulfur. In FIG. 1 this is accomplished by adjusting valves 3 and 16 so that all or a portion of the feed gas is directed through line 15, valve 16 and lines 17 and 18 to preheater 19. Prior to entering said preheater, however, an oxygen containing gas, preferaby air, is blended with the feed gas via line 20. The amount of air so introduced is any amount less than the stoichiometric amount necessary for the oxidation of H₂ S in the feed gas to SO₂ via Reaction (I); however, in the preferred operation, air is supplied via line 20 in substantially the exact stoichiometric amount necessary for the oxidation of said H₂ S to sulfur via:

    2H.sub.2 S+O.sub.2 →2S+2H.sub.2 O                   (IV)

since Reaction (IV) is known to proceed, at least in part, by Reaction (I) followed by Reaction (II), and since the latter is equilibrium-limited by water vapor, sulfur production is enhanced if the feed gas is substantially dehydrated. Hence, an optional condenser 21, or other dehydrating means, is provided to remove water via line 22. The amount of water so removed depends upon the operating characteristics of the condenser 21 and the amount of feed gas processed through valve 23 versus the amount allowed to pass through valve 16. Preferably, however, all of the feed gas is fed via valve 23 to condenser 21 to remove sufficient water so that the feed gas entering line 17 contains less than about 15%, preferably less than about 10% by volume, of water vapor.

The mixture of feed gas and air is fed to preheater 19 wherein it is heated to a temperature of at least about 250° F. but no more than about 325° F., and then fed via line 24 to oxidation reactor 25 at a space velocity between about 250 and 2000 v/v/hr, but preferably between about 800 and 1000 v/v/hr. The gases contact a catalyst in the oxidation reactor 25 at a temperature in the range of about 250°-450° F., but preferably in the range of about 300°-400° F. The preferred catalyst is one which comprises reduced vanadium pentoxide (V₂ O₅), between about 5 and 15% by weight, on alumina; however, any of the catalysts hereinafter described in more detail for use in catalytic incinerator 11 can be used in oxidation reactor 25. When utilized in oxidation reactor 25 under the preferred conditions hereinbefore specified, these catalysts are capable of effecting an air oxidation of H₂ S to sulfur of at least 50%, and preferably at least 90%, complete, and of effecting the same without also oxidizing significant amounts of H₂, CO, NH₃, and light hydrocarbons, any or all of which may be present in the feed gas. In addition, they also retain these desired properties of high activity and selectivity for extended periods of time; their estimated life when processing suitable feed gases under the conditions hereinbefore specified is considered to be at least about one year.

The gases leaving the oxidation reactor 25 are passed via line 26 to sulfur condenser 27 which lowers the temperature of said gases to preferably between about 250° and 270° F. As the sulfur condenses, it is removed via line 28. The remaining noncondensable off-gases are then sent via lines 29 and 30 to be blended in line 5 with that portion of the feed gas, if any, which by-passes reactor 25 via line 4. This mixture of gases is then incinerated as previously described.

If desired, a portion of the gases leaving the sulfur condenser 27 via line 29 can be recycled by blower 31 through line 32, manifold line 33, and lines 34 and/or 34a directly into the oxidation reactor 25. These recycle gases can also be conducted through line 35 into line 18 to admix with the gases entering the preheater 19. The purpose in recycling these gases is primarily to prevent sulfur deposition on the catalyst by so diluting the H₂ S in the gases entering, or already in the oxidation reactor 25, that, even if it were all oxidized to sulfur, the sulfur dewpoint of said gases would still be maintained below the operating temperature of oxidation reactor 25. Secondarily, Reaction (IV) being highly exothermic, these recycle gases can maintain the oxidation temperature rise in oxidation reactor 25 within the narrow 250°-450° F. range recited hereinbefore by: (1) injecting (250°-270° F.) quench gases directly into oxidation reactor 25 via lines 34 and/or 34a, and/or (2) by diluting via line 35 the H₂ S concentration in the feed gases prior to entering the preheater 19 in a manner and for results similar to those hereinbefore set forth in Example I. With respect to this second temperature control method, the only demonstrable difference between it and that described for incinerator 11 is that for any mixture of gases entering oxidation reactor 25, the temperature rise coefficient is dependent upon the heat of reaction of Reaction (IV), rather than that of Reaction (I).

In practicing the sulfur recovery-incineration process shown in FIG. 1, it should be noted that some sulfur vapor may well be present in the feed gas entering the incinerator 11. Because the catalyst employed therein oxidizes sulfur vapor (as well as H₂ S) to SO₂, it is necessary in the preferred method of operation to blend at least sufficient oxygen via line 6 or 6a for the oxidation of both the sulfur vapor and H₂ S. Normally, however, the sulfur vapor concentration in such gases is relatively small, or even insignificant, and thus will play essentially no role in the commercial operation of the process.

Both the incineration and oxidation operations described above are preferably carried out at about atmospheric pressure, but pressures ranging between about 5-500 psia are contemplated.

The most critical aspect of the invention resides in the nature of the catalyst utilized in the incinerator. In general, catalysts comprising one or more vanadium oxides and/or sulfides supported on a non-alkaline porous refractory oxide are operative. Suitable non-alkaline supports, as defined herein, include such refractory oxides as silica, alumina, silica-alumina, silica-magnesia, zirconia, silica-zirconia, titania, silica-titania, silica-zirconia, titania, or combinations of the aforementioned materials. Acidic metal phosphates and arsenates such as aluminum phosphate, boron phosphate, chromium phosphate, rare earth phosphates, aluminum arsenate, etc., may also be used, as also may certain amorphous and crystalline aluminosilicate zeolites, including such naturally occurring zeolites as mordenite, erionite, stilbite, faujasite and the like (in their "non-alkaline" forms--as hereinafter defined). Synthetic hydrogen "Y" zeolites having a silica-to-alumina (SiO₂ /Al₂ O₃) ratio between about 4:1 and 6:1, and synthetic forms of the natural zeolites noted above can also be used with success. Preferred crystalline aluminosilicate zeolites, whether natural or synthetic, consist of silica and alumina in a ratio between about 4:1 and 100:1. Especially preferred, however, are those natural and synthetic crystalline aluminosilicate zeolites having a silica-to-alumina ratio between about 6:1 and 100:1, mordenite and erionite, particularly in the hydrogen or decationized forms, being found to be most suitable.

The "non-alkaline supports" employed herein may be characterized as materials which contain no more than about 4 weight percent, preferably less than about 2 weight percent, of alkali metal or alkaline earth metal compounds, calculated as oxides, which compounds are sufficiently basic to form salts with anionic oxides of the active metal component, e.g., vanadates. Such salt formation is believed to be at least one alkali-induced transformation leading to rapid deactivation of the catalyst. Sodium zeolites are exemplary of such undesirable basic compounds.

Alumina is a preferred support, particularly in the presence of large quantities of water vapor. However, it has also been discovered, as will be shown hereinafter in Examples IV and X, that in the presence of excessive amounts of SO₂ and O₂, alumina based catalysts appear to be susceptible to sulfation, and consequent gradual deactivation. Evidently, SO₂ and O₂ react on the catalyst surface to sulfate and catalyst, either directly or indirectly via the intermediate formation of SO₃. (This discovery probably best explains the lack of commercialization of the process described in United Kingdom Pat. No. 733,004 which teaches the use of catalysts comprising V₂ O₅ on alumina for H₂ S incineration of Claus tail gases.) Hence, although alumina based catalysts are operable in the wide range of conditions specified hereinbefore, their lives are probably somewhat limited when they are used to process feed gas-oxidant mixtures containing more than about 1 to 1.5 mole% H₂ S. It is therefore recommended that when alumina based catalysts--or other sulfatable supported catalysts comprising silica-magnesia, zirconia, silica-zirconia, titania, silica-titania, silica-zirconia-titania, etc.,--are to be used for processing feed gas-oxidant mixtures containing more than about 1 mole % H₂ S, that conditions be chosen for operation which reduce the likelihood of catalyst sulfation. Among these include lower operating temperatures, the use of externally derived diluent gases, and the use of oxygen or air in amounts at or just slightly above the stoichiometric (for Reaction (I)) amount required to convert all of the H₂ S to SO₂.

The remaining catalyst supports hereinbefore mentioned have been found to be stable in the presence of SO₃ or SO₂ plus O₂ and their use in environments containing such reactants is normally preferred, depending upon other environmental factors. Silica, for example, does not sulfate but because of its well-known susceptibility to decomposition and volatilization in the presence of water vapor, it should not be used in environments wherein the water dew point can exceed about 120° F. Likewise, amorphous aluminosilicates (unless steam stabilized so as to maintain a surface area above about 200 m² /gm in the presence of steam) should not be used if the water dew point can exceed about 150° F. On the other hand, crystalline aluminosilicates having a silica-to-alumina mole-ratio between about 4:1 and 100:1, and particularly those having a silica-to-alumina ratio between about 6:1 and 40:1, are largely immune to attack by water vapor, SO₃ or SO₂ plus O₂. Thus, hydrogen "Y" zeolite, hydrogen mordenite and hydrogen erionite are excellent examples of catalyst supports which will render long and useful service over a wide range of operating conditions. Hydrogen mordenite is especially preferred because of its substantial immunity to SO₃ or SO₂ plus O₂ attack. Even when prepared in the wide silica-to-alumina ratios from about 10:1 to about 100:1, hydrogen mordenite is extremely SO₃ -resistant. In ratios higher than about 40:1, however, the hydrogen mordenite tends to become unstable hydrothermally; consequently, the preferred catalyst support in the presence of SO₃ (or SO₂ plus O₂) and/or water vapor is one composed of hydrogen mordenite with a silica-to-alumina ratio between about 10:1 and about 40:1.

The foregoing supports are compounded as by impregnation, with from about 0.2 to 30 weight percent, preferably 2 to 20 weight percent, of a vanadium promoter. Specifically, any oxide and/or sulfide of vanadium will perform satisfactorily. The preferred active metal component, however, is vanadium pentoxide (V₂ O₅) in proportions between about 1 and 30% by weight. Especially preferred, however, is a catalyst comprising between 2 and 20 weight percent V₂ O₅, more preferably between about 5 and 15 weight percent V₂ O₅.

After being pelleted or extruded, the catalyst is subsequently dried and calcined at 800°-1200° F. for about 1-12 hours. If reduction is necessary (i.e., because the catalyst is to be utilized in oxidation reactor 25), it can be accomplished by passing a mixture of gases consisting of 10 mole % H₂ S and 90 mole % H₂ at a temperature of about 400° F. and at a space velocity between about 400 and 600 v/v/hour over the catalyst for about two hours. If a reduced catalyst is used in incinerator 11, it can effect the intended air oxidation of H₂ S to SO₂ ; however, the operating conditions in said incinerator 11 are such that the active metal promoter will eventually become oxidized and/or sulfided.

One catalyst of the invention is prepared as follows:

10% V₂ O₅ on alumina:

200 gm of Al₂ O₃ (as hydrated spray-dried alumina) was soaked in a hot solution of 28.5 gm of NH₄ VO₃ in 500 ml water. The paste so formed was dried at 90°-100° F., remoistened and extruded through a 1/8 inch die, dried at 212° F. and calcined at 932° F. for 3 hours.

Under favorable circumstances this catalyst is known to be able successfully to incinerate H₂ S with no measurable loss of activity after 30 days operation. Its useful life is considered to be about a year. An incineration of H₂ S to SO₂ between about 90 and 100% complete can be expected from this catalyst when utilized under the conditions shown in the following four Examples. (It should be noted that all feed and product compositions shown in these four Examples are reported on a dry mole-percent basis and that the water dew point of each of the feed gases, unless otherwise specified, was 55° F.).

EXAMPLES II and III

A waste gas having the dry composition shown in Table I was blended with excess air such that 1.5 times the stoichiometric amount of oxygen necessary for Reaction (I) was available as a reactant, and the resultant mixture was passed at a pressure slightly above atmospheric and at a space velocity of 1752 GHSV over a catalyst comprising 10% V₂ O₅ on Al₂ O₃, prepared substantially as above described. The incinerator temperature was maintained isothermally at 400° F. No recycle or other diluent gases were used. A product gas of the indicated dry composition was obtained. Another waste gas having the dry composition shown in Table II was treated similarly except that an isothermally-held incinerator temperature of 350° F. was used. A product gas having the dry composition shown in Table II was obtained. As shown in both Examples, essentially complete conversion of the H₂ S to SO₂ was effected and essentially no oxidation of H₂, CO or CH₄ occurred.

                  TABLE I                                                          ______________________________________                                         Gas Component Mole % in Feed                                                                              Mole % in Product                                   ______________________________________                                         Hydrogen      5.3372       5.3371                                              Carbon Monoxide                                                                              0.7407       0.8086                                              Methane       0.0357       0.0352                                              Nitrogen      87.6917      87.6628                                             Oxygen        0.0126       0.0374                                              Hydrogen Sulfide                                                                             0.0196       0.0006                                              Argon         0.0389       0.0430                                              Carbon Dioxide                                                                               6.0594       6.0332                                              Methyl Mercaptan                                                                             0.0003       0.0004                                              Carbonyl Sulfide                                                                             0.0055       0.0066                                              Sulfur Dioxide                                                                               0.0186       0.0352                                              Carbon Disulfide                                                                             0.0          0.0001                                              Total Sulfur  0.0440       0.0430                                              Compounds.sup.(1)                                                              Overall H.sub.2 S Conversion                                                   = 96.94%                                                                       ______________________________________                                          .sup.(1) Expressed as moles of SO.sub.2 aor monatomic sulfur compounds.  

                  TABLE II                                                         ______________________________________                                         Gas Component Mole % In Feed                                                                              Mole % In Product                                   ______________________________________                                         Hydrogen      5.4118       5.4964                                              Carbon Monoxide                                                                              0.8629       0.8661                                              Methane       0.0360       0.0362                                              Nitrogen      87.3931      87.3036                                             Oxygen        0.0103       0.0583                                              Hydrogen Sulfide                                                                             0.0066       0.0000                                              Argon         0.0416       0.0439                                              Carbon Dioxide                                                                               6.2357       6.1853                                              Methyl Mercaptan                                                                             0.0003       0.0004                                              Carbonyl Sulfide                                                                             0.0001       0.0011                                              Sulfur Dioxide                                                                               0.0018       0.0088                                              Carbon Disulfide                                                                             0.0001       0.0000                                              Total Sulfur  0.0090       0.0103                                              Compounds.sup.(1)                                                              Overall H.sub.2 S Conversion                                                   = 100%                                                                         ______________________________________                                          .sup.(1) Expressed as moles of SO.sub.2 or monatomic sulfur compounds.   

EXAMPLE IV

In seven different experimental runs, a feed gas-air mixture (water vapor dew point=68° F.) having the average dry composition shown in Table III was passed over the 10% V₂ O₅ on Al₂ O₃ catalyst hereinbefore described. Each run was conducted at a different isothermally held temperature but in all other respects the runs were identical. No recycle or other diluent gases were used. Other pertinent data concerning the runs were as follows: Pressure=3-15 in. H₂ O (above atmospheric); GHSV=4189; Excess Air Available=1.5 times stoichiometric (for Reaction (I)). The results were as follows:

                                      TABLE III                                    __________________________________________________________________________     Run No.          1     2     3     4     5     6     7                         Temperature ° F.                                                                         402   503   604   700   803   854   902                       Component  Feed                                                                __________________________________________________________________________     H.sub.2 mol %                                                                             16.67 16.73 17.10 16.90 16.32 16.07 16.13 13.44                     CH.sub.4 mol %                                                                            12.13 12.22 12.23 12.36 12.47 12.41 12.49 13.04                     N.sub.2 mol %                                                                             11.71 11.63 11.80 11.95 11.32 11.46 12.14 12.39                     O.sub.2 mol %                                                                             2.82  2.21  0.86  0.75  0.48  0.44  0.23  0.00                      Ar mol %   0.13  0.14  0.13  0.14  0.14  0.14  0.14  0.15                      CO.sub.2 mol %                                                                            55.28 56.17 55.83 55.79 56.87 57.01 56.69 59.33                     H.sub.2 S ppmv                                                                            12234 4579  227   23    50    33    22    6328                      CH.sub.3 SH ppmv                                                                          13.6  15    0     0     0     13    0     15                        COS ppmv   18.3  9     9     12    24    29    21    683                       SO.sub.2 ppmv.sup.2                                                                       152   3441  12518 13092 12926 13244 13455 5819                      CS.sub.2 ppmv                                                                             5.6   4     8     5     3     7     5     8                         Total S                                                                        Compounds, ppmv.sup.1,2                                                                   12430 8051  12771 13137 13001 13333 13408 12861                     % H.sub.2 S Conversion                                                                          62.6  98.14 99.812                                                                               99.591                                                                               99.730                                                                               99.820                                                                               48.3                      __________________________________________________________________________      .sup.1 Expressed as ppmv SO.sub.2 or ppmv monatomic sulfur compounds.          .sup.2 The slight increase of total sulfur compounds is due to analytical      errors in determining SO.sub.2 ; SO.sub.2 values should be somewhat lower                                                                               

It is seen from the foregoing that a conversion of H₂ S to SO₂ at least 98% complete is effected whenever the exit gas temperature of the incinerator is maintained between about 500° and 850° F. Also, a conversion between 99 and 100% complete is consistently obtained when the exit gas temperature is maintained between 600° and 850° F. The high content of H₂ S in the product gas from Run 7 apparently means either that, when the oxygen becomes depleted, hydrogen begins to combine with SO₂ to reform H₂ S (Reaction III), or that at about 900° F. hydrogen begins to react with O₂ to form water, thus depleting the O₂ available for oxidizing H₂ S. In any event it is apparent that temperatures in excess of 900° F., at least with the instant catalyst, result in some oxidation of H₂ to water and some reaction of CO₂ with H₂ S to form COS. Lastly, it is concluded that essentially no SO₃ forms at temperatures below about 900° F. because any available hydrogen would reduce the SO₃ to SO₂ and water; since no loss in hydrogen is found below 900° F. in Table III, no demonstrable evidence of SO₃ production is found. This result is considered surprising inasmuch as vanadia catalysts used in the sulfuric acid industry are known to be very active for oxidizing SO₂ to SO₃ even at temperatures as low as 750° F.

EXAMPLE V

In a run to demonstrate the effectiveness of the combined sulfur recovery-incineration process shown in FIG. 1 and described in more detail hereinbefore, a waste gas was utilized having the following dry feed composition in mole %:

    ______________________________________                                         H.sub.2                                                                               5.5380      Ar          0.0412                                          CO     0.7965      CO.sub.2    6.2010                                          CH.sub.4                                                                              0.0367      CH.sub.3 SH 0.0004                                          N.sub.2                                                                               87.3190     COS         0.0011                                          O.sub.2                                                                               0.0093      SO.sub.2    0.0164                                          H.sub.2 S                                                                             0.0403      CS.sub.2    0.0                                             Total Sulfur Compounds.sup.(1)                                                                        0.0582                                                  ______________________________________                                          .sup.(1) Expressed as moles of SO.sub.2 or monatomic sulfur compounds    

This feed gas was blended with air such that a stoichiometric amount of oxygen (for Reaction (IV)) was available as a reactant. The resultant mixture was fed at 325° F. and 876 GHSV to an oxidation reactor containing a catalyst of the same composition as those used in Examples II through IV herein except that it was reduced with a reducing gas mixture of 90% H₂ - 10% H₂ S passed over said catalyst at a temperature of about 400° F. and at a space velocity of 500 v/v/hour for about 2 hours. The gases within the oxidation reactor were maintained at about 325° F. by external cooling means. The gases leaving the oxidation reactor were passed through a sulfur condenser which cooled the gases to 260° F. and removed sulfur. No recycle gases were used for temperature control or for dilution of sulfur vapors. The off gas from the sulfur condenser had the dry composition shown in the first column of Table II and was further treated as described in Example III. The results obtained were those shown in the second column of Table II.

Each of the following three Examples describes a preferred catalyst useful in the incineration and oxidation steps.

EXAMPLE VI

600 gm Zeolon, a commercial synthetic sodium mordenite manufactured by the Norton Company, was slurried in 5000 ml 1.0 N HCl at room temperature for 60 minutes. It was then filtered and the treatment was repeated on the filter cake. The filter cake from the second treatment was slurried in hot 1.0 N HCl (73° C.) for one hour, then filtered, and finally washed on the filter with four 1000 ml washes of hot water. After the filter cake was dried, the Na₂ O content was 0.57% by weight (about 93% exchanged to the hydrogen form). The hot treatment was repeated twice more for 45 minutes each, after which time the Na₂ O level was 0.21% by weight (97.5% exchanged). The amount of aluminum extracted was relatively small, so the product had a SiO₂ /Al₂ O₃ ratio of 11.5 compared to the original ratio of 10.

An amount of the dried hydrogen mordenite, corresponding to 225 gm of anhydrous powder, was mulled together with 424 gm of a silica hydrogel (containing about 6% SiO₂ or 25 gm of anhydrous silica) and 36.1 gm of NH₄ VO₃ (or 27.8 gm of V₂ O₅). The mixture was dried during mulling with a flow of hot air until it was of extrudable consistency. It was then extruded through a 1/8-inch die, dried, and calcined at 932° F. for 3 hours. The product containing 10% by weight of V₂ O₅ had excellent physical properties and had a deep golden color.

EXAMPLE VII

A silica hydrogel was prepared in a manner similar to that used for the preparation of the hydrogel binder of Example VI. Two solutions (A) and (B) were prepared as follows:

(A) 70 ml of concentrated (96%) H₂ SO₄ was diluted to 2500 ml with deionized water and cooled to 10° C.;

(B) 655 ml of 41 Be commercial sodium silicate (sp. gr. 1.394, 28.65 wt. % SiO₂ and 8.90 wt. % Na₂ O) was diluted to 2500 ml with deionized water and cooled to 10° C. When equal volumes of (A) and (B) were mixed, the pH was too low for rapid gelation, so 3.0 gm NaOH was dissolved in solution (B).

Solution (B) was poured rapidly into Solution (A); with stirring and after 41/2 minutes the mixture set to a vibrant hydrogel. After syneresis overnight, the hydrogel was cut into 1/2- to 1-inch pieces and placed on a large Buchner funnel. It was washed free of sodium by soaking in 0.3 N HNO₃ for half an hour, followed by draining and repeating of this sequence four times. The product so formed was then washed with water in the same way for a total of five times.

The hydrogel was partially dried and then mulled with enough NH₄ VO₃ to give 10% by weight of V₂ O₅ and 90% by weight of SiO₂ in the final calcined product. The moisture content of the mulled mixture was adjusted until an extrudable product was formed. It was then extruded, dried, and calcined as in Example VI.

EXAMPLE VIII

An aluminum phosphate hydrogel was prepared substantially as described in Example IV of U.S. Pat. No. 3,147,227. A slight excess of Al₂ O₃ (5-10%) remained in the preparation in order to preserve a high surface area. This hydrogel was combined with 10% V₂ O₅ as in Example VII and finished in the same way.

The following Example demonstrates the ability of the catalyst of Example VI to oxidize H₂ S to SO₂.

EXAMPLE IX

In seven different experimental runs, a feed gas-air mixture (water vapor dew point=68° F.) having the average dry composition shown in Table IV was passed over the catalyst prepared as described in Example VI. Each run was conducted at a different isothermally held temperature but in all other respects the runs were identical. No recycle or other diluent gases were used. Other pertinent data concerning the runs were as follows: Pressure=3.5-5.3 in. H₂ O (above atmospheric); GHSV=4189; Excess Air Available=1.5 times stoichiometric (for Reaction (I)).

The results obtained are summarized in columns 1 through 7 of Table IV. It was observed that results with this catalyst with respect to percent H₂ S oxidized were similar to those produced by the alumina based catalyst of Example IV. Additionally, this catalyst appeared to perform better at high temperatures inasmuch as less COS was formed, less H₂ was oxidized and the oxidation of H₂ S to SO₂ was almost complete. (However, as will be explained more fully in Example XI, these results are probably not related as much to the performance of the catalyst as they are to the fact that oxygen was present in the product gas in this Example and none was available in run 7 of Example IV). Also, this example shows that the presence of NH₃ in the feed gas had no noticeable effect upon the performance of the catalyst.

                                      TABLE II                                     __________________________________________________________________________     Run No.            1     2     3     4     5     6     7                       Temperature of Run, ° F.                                                                   502   601   701   802   853   883   903                     Component    Feed                                                              __________________________________________________________________________     H.sub.2, mol %                                                                              16.48 16.94 16.61 15.59 16.34 15.78 15.62 15.82                   CH.sub.4, mol %                                                                             12.03 12.19 12.39 12.58 12.34 12.50 12.77 12.56                   N.sub.2, mol %                                                                              11.46 11.73 11.73 12.05 11.81 11.67 12.06 11.65                   O.sub.2, mol %                                                                              2.79  0.99  0.55  0.09  0.41  0.41  0.35  0.14                    Ar, mol %    0.13  0.14  0.14  0.14  0.14  0.14  0.14  0.13                    CO.sub.2, mol %                                                                             55.88 56.84 57.29 58.32 57.72 58.11 57.77 58.33                   H.sub.2 S, ppmv                                                                             12059 316   27    108   26    23    16    26                      CH.sub.3 SH, ppmv                                                                           13    0     0     0     0     4     0     15                      COS, ppmv    15    14    17    30    34    49    27    27                      SO.sub.2, ppmv.sup.2                                                                        193   11306 12874 12271 12307 13826 12907 13594                   CS.sub.2, ppmv                                                                              6     30    4     7     7     8     6     6                       NH.sub.3, ppmv                                                                              500   --    --    --    --    --    --    --                      Total S                                                                        compounds, ppmv.sup.1,2                                                                     12292 11696 12926 12423 12381 13918 12962 13674                   % H.sub.2 S Conersion                                                                       --    97.3796                                                                              99.7761                                                                              99.1044                                                                              99.7844                                                                              99.8093                                                                              99.8673                                                                              99.7844                 __________________________________________________________________________      .sup.1 Expressed as ppmv SO.sub.2 or ppmv monatomic sulfur compounds.          .sup.2 The slight increase of total sulfur compounds is due to analytical      errors in determining SO.sub.2 ; SO.sub.2 values should be somewhat lower                                                                               

The following Example shows how resistant the mordenite based catalysts are to sulfation.

EXAMPLE X

A 10% V₂ O₅ on alumina catalyst prepared in the manner set forth hereinbefore and a catalyst prepared as described in Example VI were each used to incinerate H₂ S in a feed gas - air mixture (water vapor dew point=68° F.) having the nominal feed compositions shown in Tables III and IV, respectively. After the alumina based catalyst had been continuously used for 8 days and the mordenite based catalyst for 18 days under identical operating conditions of: pressure 3.5-15 in. H₂ O (above atmospheric); GHSV=4189; excess Air available=1.5 times stoichiometric (for Reaction (I)); operating temperature range 300°-950° F.; the catalysts were analyzed for sulfur content by means of an induction furnace analytical technique (ASTM D-1552 modified for determination of sulfur in inorganic solids). The alumina based catalyst was found to contain 2.21% sulfur while the mordenite based catalyst contained only 0.54% sulfur. Since no sulfur could be leached from either catalyst by a carbon disulfide extraction, it was concluded that the sulfur was present in the catalysts as sulfate. Thus, although the mordenite based catalyst was used to incinerate H₂ S for 10 more days of sustained operation than the alumina based catalyst, it was found to be sulfated less than 25% as much.

The following Example illustrates the use of a silica based catalyst in the invention.

EXAMPLE XI

In four experimental runs utilizing a first feed gas-air mixture, and in three other runs utilizing a second feed gas-air mixture (all having a water vapor dew point=68° F.), the respective gas mixtures were passed over the catalyst of Example VII (SiO₂ gel base). The feed gases had the dry compositions designated first feed and second feed in Table V. Each run was conducted at a different isothermally held temperature but in all other respects the runs were identical. No recycle or other diluent gases were used. Other pertinent data concerning the runs were as follows: Pressure=5.4-8.0 in. H₂ O (above atmospheric); GHSV=4189; Excess Air Available=1.5 times the stoichiometric amount (for Reaction (I)) in first feed and 2.0 times the stoichiometric amount (for Reaction (I)) in second feed.

The results obtained are summarized in columns 1 through 7 of Table V. It was observed that results with this catalyst with respect to percent H₂ S oxidized were similar to those obtained with the alumina based catalyst of Example IV and the mordenite based catalyst of Example IX. In addition, two other facts were apparent:

(1) In comparing columns 4 and 7 of Table V it appears obvious that if oxygen is available in the product gas at temperatures above about 900° F., no H₂ S is produced via Reaction (III) nor is any appreciable amount of COS formed. It appears likely that when less than about 2 times the amount of excess air required for Reaction (I) is present at temperatures in excess of 900° F., the oxidation of H₂ with O₂ takes place to some extent in competition with Reaction (I). Once the oxygen is depleted, conditions evidently become favorable for Reaction (III).

(2) Since 2.0 times the stoichiometric air was used to produce the results of column 7, it was surprising that no significant loss of hydrogen was detected. Also, no SO₃ was produced even under temperature and oxidizing conditions most likely to lead to such a result. This conclusion was confirmed by the fact that when the product gases obtained from the experiment described herein were bubbled through a water bath no "SO₃ plume" was seen emanating therefrom. Similarly, no "SO₃ plane" was found when the product gases obtained in the experiments of Examples IV and IX were bubbled through water baths. Hence, the process of the invention produces essentially no SO₃, even when sufficient oxygen is available to oxidize at least some of the produced SO₂ to SO₃.

                                      TABLE V                                      __________________________________________________________________________     Run No.         1     2     3     4           5     6     7                    Temperature                                                                    of Run. ° F.                                                                            503   703   883   953   703   883   953                                  1st                           2nd                                    Component Feed                          Feed                                   __________________________________________________________________________     H.sub.2, mol %                                                                           15.59 16.08 15.04 14.94 11.44 14.20 14.42 12.98 11.55                CH.sub.4, mol %                                                                          12.09 12.02 12.44 12.46 13.28 10.61 10.82 10.92 11.18                N.sub.2, mol %                                                                           11.65 11.95 11.81 12.10 12.54 18.81 19.33 19.76 20.33                O.sub.2, mol %                                                                           2.85  1.04  0.47  0.12  0.00  4.74  2.86  2.43  1.34                 Ar, mol % 0.13  0.13  0.14  0.60  0.15  0.22  0.22  0.23  0.24                 CO.sub.2, mol %                                                                          56.39 57.41 58.72 58.30 61.36 50.34 51.19 52.50 54.14                H.sub.2 S, ppmv                                                                          12714 431   23    20    9187  10558 22    21    23                   CH.sub.3 SH, ppmv                                                                        9     2     0     0     8     4     0     0     0                    COS, ppmv 12    13    33    61    1437  17    16    35    31                   SO.sub.2, ppmv.sup.2                                                                     173   13252 13770 14641 1693  238   11524 11720 12144                CS.sub. 2, ppmv                                                                          4     9     6     5     28    5     7     14    6                    NH.sub.3, ppmv                                                                           500   --    --    --    --    500   --    --    --                   Total S                                                                        compounds, ppmv.sup.1,2                                                                  12916 13716 13838 14732 12381 10827 11576 11804 12210                % H.sub.2 S Conversion                                                                   --    96.61 99.82 99.84 27.74 --    99.79 99.80 99.78                __________________________________________________________________________      .sup.1 Expressed as ppmv SO.sub.2 or ppmv monatomic sulfur compounds.          .sup.2 The slight increase of total sulfur compounds is due to analytical      errors in determining SO.sub.2 ; SO.sub.2 values should be somewhat lower                                                                               

EXAMPLE XII

In another experimental run an H₂ O-containing feed gas stream at a water vapor dew point of about 75° F. was blended at 266.6 scc/min (dry basis as measured at 60° F.) with (a) sufficient air, fed at the rate of 7.0 scc/min, to provide about 9.26 times the stoichiometric amount of oxygen necessary to convert the H₂ S to SO₂ and (b) and NH₃ -containing gas produced by vaporizing an aqueous ammonia solution containing 8.78 g NH₃ /l and having a pH of 10.9 at the rate of 6.1 ml/hr. The feed gas had a dry composition as shown in Table VI. The mixed blend of feed gas, air, and vaporized ammonia solution was passed at a pressure slightly above atmospheric into an incinerator containing a catalyst prepared as described in Example VI. The temperature of the incinerator was maintained isothermally at 700° F. and the gases were placed therethrough at a space velocity of 4000 GHSV. The gaseous effluent obtained from the incinerator was cooled so as to condense water at 70° F., thereby leaving a product gas of composition shown in Table VI.

The experiment was continued over a 24-hour period. A total of 147 ml of aqueous ammonia solution was vaporized and blended with the feed gas stream while 148 ml of condensate was collected. The condensate had a pH of 7.3 and contained 8.78 g/l of ammonia, 12.1 g/l of dissolved SO₂, and essentially no H₂ S, thereby indicating that essentially all the H₂ S had been converted to SO₂ and that essentially all the ammonia that entered the incinerator had passed through the catalyst bed without being oxidized. Hence, the process of the invention is not only selective for oxidizing H₂ S to SO₂ in the presence of H₂, CO, and light hydrocarbons, but also in the presence of ammonia.

                  TABLE VI                                                         ______________________________________                                         Component .sup.1                                                                              Feed Gas .sup.2                                                                             Product Gas                                        ______________________________________                                         H.sub.2, mol % 4.11         3.98                                               CO.sub.2, mol %                                                                               1.00         0.95                                               N.sub.2, mol % 94.78        94.83                                              O.sub.2, mol % 0.00         0.16                                               CH.sub.4, ppmv 192          193                                                H.sub.2 S, ppmv                                                                               397          0                                                  Ar, ppmv       354          603                                                CH.sub.3 SH, ppmv                                                                             1            1                                                  COS, ppmv      5            10                                                 SO.sub.2, ppmv 99           10                                                 Nh.sub.3, ppmv N.D..sup.3   42                                                 ______________________________________                                          .sup.1 All values in Table VI were obtained by mass spectrometrical            analysis except those for NH.sub.3, which were obtained by calculation,        .sup.2 The composition data of the feed gas indicates the concentration o      constituents therein prior to having the NH.sub.3 -containing gas blended      therewith.                                                                     .sup.3 Not determined. The ammonia concentration in the feed gas was           believed to be less than 200 ppmv. An ammonia balance based on 200 ppmv i      the feed gas would show that the total loss of ammonia through the             incinerator was about 3.7%.                                              

The following Example compares the hydrolytic stability of a mordenite based catalyst and a silica based catalyst.

EXAMPLE XIII

A 10% V₂ O₅ -mordenite based catalyst prepared as described in Example VI, and a 10% V₂ O₅ on silica catalyst prepared as described in Example VIII were steamed at 850° F. for 112 hours. Saturated steam was used. The physical characteristics of the catalysts after this severe hydrothermal treatment are shown in Table VI.

                  TABLE VI                                                         ______________________________________                                         Physical  Vanadia-Mordenite                                                                             Vanadia-Silica                                        Characteristics                                                                          Fresh   After Steam                                                                               Fresh After Steam                                 ______________________________________                                         Crushing                                                                       Strengths,                                                                     pounds per 1/8"                                                                          7.0     6.3        2.7   2.3                                         Surface Area,                                                                  m.sup.2 /gm                                                                              467     349        554   296                                         ______________________________________                                    

In a specific embodiment of the invention, the H₂ S in the vent gases emanating from geothermal power plants is incinerated. As shown in FIG. 2, these power plants send geothermal steam containing usually between about (by weight) 100-500 ppm H₂ S, 100-800 ppm CH₄ and 25-300 ppm H₂, through lines 40 and 50 to a turbine 60. The exhausted steam is passed via conduit 70 to a contact condenser 80 wherein it is condensed by intimate intermingling with 40°-150° F. cooling water from lines 90 and 100. The resulting mixture is then routed through lines 110 and 120 to a cooling tower 130, in which the heat absorbed by the cooling water is released to a cross or countercurrently flowing air stream. Off gases (i.e., air plus gases stripped from the cooling water in the cooling tower) are then emitted to the atmosphere via line 140.

Only some of the H₂ S in the exhausted steam is soluble in the cooling water; thus, a portion of H₂ S is emitted from the cooling tower via line 140 and the remainder is withdrawn from the condenser with the other noncondensable gases. Normally, the H₂ S from the condenser is discharged to the atmosphere with the other noncondensable gases by means of a jet ejector. By the process of this invention, however, these gases are sent by jet ejector 160 through line 150, 1, 2, 4, and 5 to effect ultimate incineration of the H₂ S contained in said gases by one of the embodiments hereinbefore described with reference to FIG. 1. Alternatively, prior to incineration, all or a portion of the noncondensable gases can be routed by jet ejector 160 to line 15 to be treated by one of the embodiments hereinbefore described with reference to FIG. 1, in which the oxidation reactor 25 converts to elemental sulfur at least 50%, and preferably 90%, of the H₂ S contained in said noncondensable gases. In either case, the purified off gases can then be discharged from the incinerator 11 to the atmosphere via line 12. However, they are preferably conducted via conduit 170 to a conventional SO₂ scrubber 180 wherein SO₂ is dissolved in an aqueous solvent and the remaining purified gases are discharged to the atmosphere through line 200.

A preferred aqueous medium for absorbing SO₂ in SO₂ scrubber 180 is a portion of the cooling water from cooling tower 130, which portion may be diverted to scrubber 180 via line 240. If desired, caustic or lime can be added via line 190 to increase the absorbtion of SO₂ in scrubber 180. However, since SO₂ is partially soluble in aqueous solutions having a pH as low as 3.5, the cooling water, which desirably is maintained in the pH range of about 5.5-7.5, is preferably used without adding alkaline chemicals.

Normally, the waste water from the SO₂ scrubber 180 is discharged to waste via line 210 and 220. In the preferred mode of operation, however, at least a portion of this waste water is directed via lines 210, 230, and 120 to cooling tower 130 to maintain the cooling water in the desired pH range of 5.5-7.5. It will be understood that geothermal steam normally contains some ammonia, which would build up in the cooling water, raising its pH to above 7.5, thereby creating potential scaling problems, especially if ground waters are used as partial make-up to the cooling water system. Thus, this embodiment of the invention relieves the geothermal power plant of reliance on chemicals for cooling water pH control. Additionally, if the waste water containing dissolved SO₂ aids in dropping the pH of the cooling water into the lower part of the 5.5-7.5 pH range, e.g. 5.5-6.0, H₂ S absorption by the cooling water in the contact condenser will be reduced. Therefore, more H₂ S would be withdrawn as a noncondensable gas via line 150, and less would be discharged from the cooling tower. Finally at least a portion of the H₂ S that is absorbed by the cooling water would form elemental sulfur via the aqueous Claus Reaction (II), thus further reducing H₂ S discharges from the cooling tower.

As hereinbefore set forth, externally derived gases can be utilized for temperature control purposes in incinerator 11. FIG. 2 shows the use of geothermal steam as one such externally derived gas being added as a diluent via lines 260 and 280. Although the catalysts of the invention, especially one comprising V₂ O₅ on alumina, are physically stable even in the presence of saturated steam, it is anticipated that saturated or wet-saturated steam might decrease the activity of the catalyst for incinerating H₂ S. This may be caused either by condensation of water in the catalyst pores or by the displacement of adsorbed H₂ S from the catalyst's active sites. In either event, to prevent catalyst deactivation, the steam is preferably flashed through reducing valve 270, or other suitable device, to insure contact of only dry steam with the catalyst.

As a final note to the embodiment illustrated in FIG. 2, it is conceived that such embodiment is also applicable to geothermal power plants utilizing surface condensers, rather than contact condensers as in FIG. 2. In fact, those that employ surface condensers, or can otherwise be modified to have their cooling water systems made independent of their steam cycle, permit recovery of essentially all the H₂ S as a noncondensable gas. Thus, all the H₂ S emitted by the power plant could be treated by one of the incineration, or sulfur recovery-incineration, embodiments hereinbefore described, and none would be discharged by the cooling tower.

The following Example is illustrative of the performance of the process when utilized to treat noncondensable gases emanating from geothermal power plant condensers.

EXAMPLE XIII

A geothermal power plant must treat the vent gases (water dew point=72° F.) emitted from its contact condenser. A typical dry gas composition of these vent gases is as follows (in mole %): H₂ --17.79; CH₄ --13.12; N₂ --6.26; O₂ --2.21; CO₂ --59.23; H₂ S--1.34 and NH₃ --0.05. Except for the lack of trace amounts of Ar, CH₃ SH, COS, SO₂ and CS₂ and the presence of more water vapor, this composition is very similar to the feed gas of Example IX. It can therefore be expected that when these vent gases are incinerated under the conditions specified in that Example, and at the temperatures indicated in Table IV, substantially the same results shown in columns 1 through 7 of Table IV would be obtained.

In another embodiment of the invention, the raw geothermal steam can be processed prior to entering the geothermal power plant turbine by any of the incineration embodiments hereinbefore set forth and shown schematically in FIG. 1. Another application in which H₂ S in geothermal steam can be incinerated without firstly separating it from the steam is in the purification of gaseous effluents from "wild" geothermal well. A "wild" geothermal well is a term used in the art in reference to those geothermal wells which must be continuously bled to minimize the internal pressure. Such bleeding usually discharges to the atmosphere steam containing H₂ S, CH₄ and H₂ in concentration ranges hereinbefore described. For this embodiment the use of hydrogen mordenite or alumina as catalyst supports is preferred because of their resistance to deactivation in the presence of water vapor.

The term "non-condensable gases" as employed herein refers to those gases derived from geothermal steam which remain uncondensed at 150° F. or less and at atmospheric pressure or less.

It will be apparent to those skilled in the art from the foregoing that numerous modifications of the invention are contemplated. Accordingly, any and all such embodiments are to be construed as coming within the scope of the invention as defined in the appended claims or substantial equivalents thereto. 

We claim:
 1. A process for oxidizing H₂ S to SO₂ in a feed gas containing a minor proportion of H₂ S and a substantial proportion of at least one secondary oxidizable component selected from the class consisting of H₂, CO, and light hydrocarbons, which process comprises:(1) contacting said feed gas, in admixture with sufficient oxygen to convert at least about 80% of said H₂ S to SO₂, with an oxidation catalyst at a temperature between about 300° and 900° F. and at a space velocity correlated with temperature so as to convert at least about 80% of said H₂ S to SO₂ without oxidizing substantially any of said secondary oxidizable components, said oxidation catalyst comprising a vanadium oxide and/or sulfide as the essential active component supported on a crystalline, non-alkaline porous refractory oxide comprising hydrogen mordenite having a silica-to-alumina ratio between about 10:1 and 100:1 and (2) recovering a gaseous effluent of reduced H₂ S content, but still containing essentially all of said secondary oxidizable component or components.
 2. A process as defined in claim 1 wherein said oxygen in step (1) is provided in excess of the stoichiometric amount required to oxidize said minor proportion of H₂ S to SO₂ and said secondary oxidizable component is H₂.
 3. A process as defined in claim 2 wherein said oxygen in step (1) is supplied in the form of air and said feed gas-oxygen admixture is contacted with said catalyst at a temperature between about 600° and 900° F.
 4. A process as defined in claim 2 wherein said refractory oxide comprises hydrogen mordenite having a silica-to-alumina ratio between about 10:1 and 40:1.
 5. A process as defined in claim 2 wherein said oxidation catalyst comprises between about 1 and 30 weight percent V₂ O₅.
 6. A process as defined in claim 5 wherein said feed gas comprises ammonia.
 7. A process as defined in claim 2 wherein said contacting in step (1) is controlled to convert at least about 90% of said H₂ S to SO₂.
 8. A process as defined in claim 2 wherein said feed gas is the off-gas from a preceding partial oxidation of a relatively H₂ S-rich gas wherein a substantial portion of H₂ S was oxidized to elemental sulfur followed by separation of said elemental sulfur therefrom.
 9. A process as defined in claim 8 wherein said partial oxidation was effected by contacting said H₂ S-rich gas, in admixture with sufficient oxygen to convert at least about 50% of said H₂ S to elemental sulfur, with an oxidation catalyst at a temperature between about 250° and 450° F. and at a space velocity correlated with temperature so as to convert at least about 50% of said H₂ S to elemental sulfur, said oxidation catalyst comprising a vanadium oxide and/or sulfide supported on a non-alkaline porous refractory oxide.
 10. A process as defined in claim 9 wherein said non-alkaline, porous refractory oxide of step (1) consists essentially of hydrogen mordenite having a silica-to-alumina ratio between about 10:1 and 40:1.
 11. A process for treating a feed gas stream containing, as essentially the only oxidizable components therein, H₂ S and one or more secondary oxidizable components selected from the class consisting of H₂, CO, and light hydrocarbons, said feed gas stream further containing at least sufficient oxygen to convert a substantial proportion of said H₂ S to SO₂, which process comprises:(1) maintaining the H₂ S concentration of said feed gas stream at a substantially constant value and maintaining the temperature of said feed gas stream at a substantially constant value between about 300° and 750° F.; (2) contacting said feed gas stream with an oxidation catalyst so as to convert a substantial proportion of said H₂ S to SO₂ without oxidizing substantially any of said secondary oxidizable components, said oxidation catalyst comprising a vanadium oxide and/or sulfide as the essential active component supported on a crystalline non-alkaline porous refractory oxide comprising hydrogen mordenite having a silica-to-alumina ratio between about 10:1 and 100:1; and (3) recovering a gaseous effluent of reduced H₂ S content, but still containing essentially all of the secondary oxidizable component or components originally present in said feed gas stream, said gaseous effluent being at a substantially constant temperature between about 500° and 900° F., and said constant temperature being such that the temperature rise in step (2) is substantially constant and substantially directly proportional to the concentration of the H₂ S in said feed gas stream.
 12. A process as defined in claim 11 wherein said secondary oxidizable component is H₂.
 13. A process as defined in claim 12 wherein said oxygen is supplied in excess of the stoichiometric amount required to oxidize said H₂ S to SO₂.
 14. A process as defined in claim 13 wherein said feed gas stream contains CO and H₂.
 15. A process as defined in claim 11 wherein said feed gas stream contains CO and H₂. 